RU2650270C1 - Apricot compote sterilization method - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: apricot compote sterilization method involves the installation of cans with the product after being rolled into a carrier, preventing the lids from being torn off during the heat treatment. Cans are cooled in the upper row of the first heat treatment zone with water at a temperature of 40 °C for 6 min. Water can be heated to 58–60 °C and flows down to the banks in the bottom row of the first zone, heating them. Banks are transferred to the second zone, where the cans are cooled in the upper row with water at a temperature of 60 °C, which heats up to 78–80 °C and drains by heating the cans in the bottom row of the second zone for 6 minutes. Banks are transferred to the third zone, where the cans are cooled in the upper zone by water at a temperature of 80 °C, which heats up to 95–98 °C and drains, heating the jars in the bottom row of the third zone for 6 minutes. Banks are transferred to the fourth zone, where the heating is carried out with air at a temperature of 140 °C and a speed of 8.0 m/s for 8 minutes. Then the banks enter the upper row of the third zone to continue the heat treatment. Water after heating in the first and second zones is used for cooling in the upper row of second and third zones. Water after heating in the third zone is used to mix and heat water to the required temperature in all cooling zones. During the heat treatment, the cans with the product rotate from the bottom to the lid at a frequency of 0.13 s^-1.

EFFECT: invention provides higher quality of final product.

1 cl

Description

The proposed method for the invention relates to the canning industry and can be used in the production of stewed apricots in cans 1-82-500.

Sources that were searched by this method showed that the prototype of the proposed method is a method of sterilizing canned "Apricot compote" in an autoclave [1] according to the mode

,

,

where 20 is the duration of the period of heating water to 100 ° C, min;

15 - the length of the period of its own sterilization at 100 ° C, min;

20 - the duration of the cooling period, min;

100 ° С - sterilization temperature, ° С;

118 - back pressure in the autoclave, kPa.

The main disadvantages of this method are:

- long duration of the process of heat treatment of the product;

- uneven heat treatment of the product in banks;

- a relatively large consumption of thermal energy and water;

- the complexity of the technical implementation, which requires the creation of a backpressure apparatus, ensuring the tightness of the cans (preventing the caps from breaking during the heat treatment).

The technical result of the proposed method is aimed at creating a method for the production of compotes, contributing to: reducing the duration of the process; more complete conservation of biologically active components contained in the raw materials used; simplify the implementation of the method and apparatus design.

The specified technical result is achieved due to the fact that the cans of the product after seaming are installed in the carrier, which ensures that the lids are not torn off during the heat treatment, and the cans of the product are preheated in the lower row of the first heat treatment zone by sweeping with water at 58-60 ° C flowing down from the cans of the upper row of the same zone and heated during cooling by water with a temperature of 40 ° C for 6 minutes, respectively. Then, the cans with the product are transferred to the second zone, where they simultaneously cool the cans in the upper row with water at a temperature of 60 ° C, which, when heated to drain from these cans to 78-80 ° C, heats the cans with the product located in the lower row of this zone, respectively, for 6 minutes, followed by transfer to the third zone, where the cans located in the upper zone are simultaneously cooled by water inlet at a temperature of 80 ° C, which, when drained from these cans, reaches a temperature of 95-98 ° C, drains and n grevaet jars with product, located on the bottom row of the zone for 6 minutes, respectively. Subsequently, the cans with the product are transferred to the fourth heating zone with heated air with a temperature of 140 ° C and a speed of 8.0 m / s for 8 minutes, after which the cans enter the upper row of the third zone to continue heat treatment, while the water after heating cans in the first and second zones are used to cool cans in the upper row of the second and third zones, respectively, and water after heating cans in the third zone is used to mix and heat water to the required temperature in all cooling zones. Moreover, in the process of heat treatment, the cans with the product rotate from the bottom to the lid with a frequency of 0.13 s ^-1 .

An example implementation of the method.

After sealing, the cans with the canned product are installed in a carrier that provides mechanical tightness (preventing caps from tearing off during the heat treatment), and enter the lower row of the first zone, where the cans with the product are cooled with water at a temperature of 40 ° C for 6 minutes in the upper row and this water, heating up when cooling these cans to 58-60 ° C, flows onto the banks of the lower row of this zone, heats the cans with the product entering this heat treatment zone. Next, the banks coming in the lower row fall into the second heat treatment zone for 6 minutes. In this zone, in the upper row there are cans with the product, which are cooled by showering with water at a temperature of 60 ° C, which, flowing down the walls of the cans of the upper zone and cooling them, while heating from them to 78-80 ° C, falls into the lower zone, where cans come from the first zone, heated to 58-60 ° C, and for 6 minutes are heated to 78-80 ° C. Then the cans from the second heat exchange zone enter the lower row of the third heat treatment zone, where in the upper row cans of the product are cooled with water with a temperature of 80 ° C for 6 minutes. Water draining from the cans of the upper row, cooling them, heats up to 95-98 ° С and, falling on the cans of the lower row, heats the cans with the product to a temperature of 95-980С for 6 minutes. After 6 minutes, the carrier is transferred to the heating zone with heated air with a temperature of 140 ° C and a speed of 8.0 m / s for 8 minutes. After this time, banks in the upper row enter the third cooling zone, and the process repeats. Moreover, in the process of heat treatment, the cans with the product rotate from the bottom to the lid with a frequency of 0.13 s ^-1 .

Water after heating the cans in the first and second zones is used to cool the cans in the upper row of the second and third zones, and water after heating the cans in the third zone is used to mix and heat the water to the required temperature in all cooling zones.

The use of cooling the cans with the product in the upper row by showering with water, which is also used to heat the cans with the product in the lower row by showering with the same water, provides an intensification of the processes of heating and cooling the product in the cans due to the intensification of heat transfer on the surface of the cans through film swelling of the water, which provides an increase heat transfer coefficient on the heat transfer surface. In addition, the use of stepwise cooling of canned food in the same areas where heating is carried out, helps to simplify the heat treatment process and the design of the sterilization apparatus, provides significant savings in heat energy and water, since with this design of heat treatment for heating canned food in all zones the heat given off by banks of the top row cooled in the same zones is used.

The salient features of the proposed method are: four-stage heating of canned food in water at temperatures of 60, 80 and 100 ° C, respectively, 6, 6 and 6 min and a stream of heated air with a temperature of 140 ° C and a speed of 8.0 m / s for 8 min followed by three-stage cooling for 6, 6 and 6 minutes, and in this case, the processes of heating and cooling the cans, except for the last stage of heating, are carried out simultaneously in the same heat treatment zones.

This mode provides significant savings in thermal energy, water, reducing the process time and thereby improving the quality of the finished product.

Literature

1. Collection of technological instructions for the production of canned food, T. 2, -M .: Food industry, 1977.

Claims (1)

A method of sterilizing apricot compote, characterized in that the cans of the product after seaming are installed in a carrier that ensures that the lids are not torn off during the heat treatment, and the cans of the product are preheated in the lower row of the first heat treatment zone by water-sweeping with a temperature of 58-60 ° C flowing down from the cans of the upper row of the same zone and heated during cooling by water at a temperature of 40 ° C for 6 minutes, respectively, followed by transfer to the second zone, where one belt cooling of the cans in the upper row with water at a temperature of 60 ° C, which, when heated to run off from these cans to 78-80 ° C, heats the cans with the product in the lower row of this zone, respectively, for 6 minutes, followed by transferring to the third zone, where the cans located in the upper zone are simultaneously cooled by water temperature 80 ° С, which, when draining from these cans to a temperature of 95-98 ° С, flows and heats the product cans in the lower row this zone for s 6 minutes, respectively, followed by transfer to the fourth heating zone with heated air with a temperature of 140 ° C and a speed of 8.0 m / s for 8 minutes, after which the cans enter the upper row of the third zone to continue heat treatment, while the water after heating the cans in the first and second zones they are used to cool the cans in the upper row of the second and third zones, respectively, and water after heating the cans in the third zone is used to mix and heat water to the required temperature in all cooling zones, while in the process of heat treatment The cans of the product can rotate from the bottom to the lid at a frequency of 0.13 s ^-1 .